Accessory factors summary 1.DNA polymerase can’t replicate a genome. SolutionATP? No single stranded templateHelicase + The ss template is unstableSSB.

Slides:

Advertisements

Similar presentations

DNA replication Learning objectives

Advertisements

Section E DNA Replication

21-1 Chapt 21 DNA Replication II: Mechanisms; telomerase Student learning outcomes: Describe how replication initiates –proteins binding specific DNA sequences.

Molecular Biology Fourth Edition Chapter 21 DNA Replication II: Detailed Mechanism Lecture PowerPoint to accompany Robert F. Weaver Copyright © The McGraw-Hill.

Berg • Tymoczko • Stryer

Bio3124 Lecture 8. Total cell DNA = genome (chromosome & extra-chromosomal) Human genome = 4 billion bp – 1000x as large as E. coli genome – 90% junk.

Initiation of Replication *Strands must separate DnaA Helicases (DnaB and DnaC) SSBPs (Single Stranded Binding Proteins) DNA gyrase (topoisomerase)

Chapter 20 DNA Replication and Repair. Watson and Crick Predicted Semi- conservative Replication of DNA Watson and Crick: "It has not escaped our notice.

Bacterial DNA replication Summary: What problems do these proteins solve? Tyr OH attacks PO4 and forms a covalent intermediate Structural changes in.

18 and 20 September, 2006 Chapter 8 DNA Replication.

DNA polymerase summary 1.DNA replication is semi-conservative. 2.DNA polymerase enzymes are specialized for different functions. 3.DNA pol I has 3 activities:

The replication of DNA. Substrates required for DNA synthesis.

Replication. Central Dogma of Information Flow Wagging the Dogma.

Bacterial Physiology (Micr430) Lecture 8 Macromolecular Synthesis and Processing: DNA and RNA (Text Chapter: 10)

1 Replication of the Genetic Material Genetic material must be duplicated for transfer into daughter cells. Complementary double-stranded DNA makes this.

DNA Replication Part 1 Principle Features. Figure 11.1 Identical base sequences Mechanistic Overview.

Chapter 13 DNA Replication.

Chromosomal Landscapes Refer to Figure 1-7 from Introduction to Genetic Analysis, Griffiths et al., 2012.

Relationship between Genotype and Phenotype

The flow of Genetic information

Chen Yonggang Zhejiang University Schools of Medicine Biochemistry.

DNA Replication AHMP 5406.

DNA Replication Part 2 Enzymology. Figure The Polymerization Reaction.

Section D: Chromosome Structure Section E: DNA replication Yang Xu, College of Life Sciences Section E DNA Replication E1 DNA Replication: An Overview.

1 Genetics Instructor: Dr. Jihad Abdallah Topic 6: DNA replication.

DNA replication Semi-conservative mechanism 1958, Meselson & Stahl 15 N labeling experiment.

Section 2 DNA Replication in Eukaryotes. Biomolecules involved in DNA replication  Substrate: dNTPs (dATP, dGTP, dCTP, dTTP)  Template unwinding parent.

A Replisome Primase Primosome DNA Polymerase III acts here

DNA Replication Lecture 7. DNA Replication  Synthesis of two new DNA duplexes based on complementary base sequences with parental DNA.  Is progressive,

چرخه سلولي Go Objectives: To know and explain about:  What are needed for Replication  Template properties  Start site of replication(

Dr. Parvin Pasalar Tehran University of Medical Sciences دانشگاه علوم پزشكي وخدمات بهداشتي درماني تهران.

Announcements 1. First lab report deadline extended by one week: X-linked cross lab report due 11/ 5,6. 2. Bookstore is closed Sundays. Buy your bluebook.

Chapter 25 DNA Metabolism Replication, Repair and Recombination Semiconservative DNA replication Each strand of DNA acts as a template for synthesis of.

-General features of DNA replication in Prokaryotic

(b) Separation of strands

DNA Replication Robert F. Waters, Ph.D.. Goals:  What is semi-conservative DNA replication?  What carries out this process and how?  How are errors.

Welcome Each of You to My Molecular Biology Class

Chapter 12 Topics Chapter 12 Topics Models of Replication Prokaryotic and Eukaryotic Replication Models of Recombination: read pp

DNA Replication  The basic rules for DNA replication

DNA Metabolism Replication, Repair, Recombination CH353 April 1, 2008.

Aging Genome 1.DNA damage 2.Epigenetic shifts 3.Telomere shortening Cellular level 1.Mitochondria: ROS, DNA damage, other 2.Misfolded proteins 3.Dysfunctional.

Helicase loading occurs at all replicators during G1.

D. Replication at the Molecular Level. 1. Replication in E. coli a. A specific sequence of bases is recognized as the binding site for the replication.

DNA Replication Tsung-Luo Jinn. Three stages of DNA Replication Initiation: primosome, a protein complex act of initiation Elongation: replisome, a protein.

Replication in Prokaryotes Chapter 6 part II. DNA replication DNA replication is semiconservative The two strands of DNA unwind with the help of DNA helicase.

The flow of Genetic information. DNA Replication  DNA is a double-helical molecule  Watson and Crick Predicted Semi-conservative Replication of DNA.

Engineering magnetosomes to express novel proteins Which ones? Must be suitable for expressing in Magnetospyrillum! Can’t rely on glycosylation, disulphide.

1 DNA Replication 複製. Ex Biochem c18-DNA replication DNA Polymerases Are the Enzymes That Make DNA DNA is synthesized in both semiconservative.

Chapter 13 DNA Replication

DNA Replication. DNA RNA protein transcriptiontranslationreplication reverse transcription Central dogma.

DNA Replication-III 28/04/2017.

Chapter 9 Replication of DNA

Chapter 12 The Replicon: Initiation of Replication

Relationship between Genotype and Phenotype

Relationship between Genotype and Phenotype

DNA REPLICATION IN PROKARYOTES

DNA Replication (II) 王之仰.

Relationship between Genotype and Phenotype

DNA REPLICATION.

Origin of Replication Primase is a Specialized RNA Polymerase

Origin of Replication Primase is a Specialized RNA Polymerase

Semiconservative Replication of DNA

Chromosomal Landscapes

DNA REPLICATION.

DNA REPLICATION.

Decoding the Genetic Code

DNA Replication and Recombination

Relationship between Genotype and Phenotype

Presentation transcript:

Accessory factors summary 1.DNA polymerase can’t replicate a genome. SolutionATP? No single stranded templateHelicase + The ss template is unstableSSB (RPA (euks)) - No primerPrimase (+) No 3’-->5’ polymeraseReplication fork Too slow and distributiveSSB and sliding clamp - Sliding clamp can’t get onClamp loader (  /RFC) + Lagging strand contains RNAPol I 5’-->3’ exo, RNAseH - Lagging strand is nickedDNA ligase + Helicase introduces + supercoils Topoisomerase II + and products tangled 2.DNA replication is fast and processive

DNA polymerase holoenzyme

Maturation of Okazaki fragments

Topoisomerases control chromosome topology Catenanes/knots Relaxed/disentangled Major therapeutic target - chemotherapeutics/antibacterials Type II topos transport one DNA through another Topos

Starting and stopping summary 1.DNA replication is controlled at the initiation step. 2.DNA replication starts at specific sites in E. coli and yeast. 3.In E. coli, DnaA recognizes OriC and promotes loading of the DnaB helicase by DnaC (helicase loader) 4.DnaA and DnaC reactions are coupled to ATP hydrolysis. 5.Bacterial chromosomes are circular, and termination occurs opposite OriC. 6.In E. coli, the helicase inhibitor protein, tus, binds 7 ter DNA sites to trap the replisome at the end. 7.Eukaryotic chromosomes are linear, and the chromosome ends cannot be replicated by the replisome. 8.Telomerase extends the leading strand at the end. 9.Telomerase is a ribonucleoprotein (RNP) with RNA (template) and reverse-transcriptase subunits.

Isolating DNA sequences that mediate initiation

Different origin sequences in different organisms E. Coli (bacteria) OriC Yeast ARS (Autonomously Replicating Sequences) Metazoans ????

Initiation in prokaryotes and eukaryotes Bacteria Eukaryotes ORC + other proteins load MCM hexameric helicases MCM (helicase) + RPA (ssbp) Primase + DNA pol  PCNA:pol   MCM (helicase) + RPA (ssbp) PCNA:pol   (clamp loader) Primase + DNA pol  PCNA:pol   DNA ligase

Crystal structure of DnaA:ATP revealed mechanism of origin assembly 1. DnaA monomer (a) forms a polar filament (b). 2. DNA binding sites occur on the outside of the filament (model). 1.2.

Crystal structure of DnaA:ATP revealed mechanism of origin assembly 1. The arrangement of DNA binding sites introduces positive supercoils by wrapping DNA on the outside. Compensating negative supercoils melt the replication bubble at the end. 2. Clamp deposition recruits Had, which promotes ATP hydrolysis and progressive disassembly of the DnaA filament (hypothesis). 1.2.

Initiation mechanism in bacteria -- 1

Initiation mechanism in bacteria -- 2

Initiation proteins in E. coli (bacteria)

10 ter sites opposite oriC coordinate the end game The ter/tus system is not essential in E. coli. Tus protein binds Ter sites and inhibits the DnaB helicase Origin Counterclockwise fork Clockwise fork Clockwise fork trap Counterclockwise fork trap

Unwinding ter from the “nonpermissive” direction springs a “molecular mousetrap” Releasing C6 springs the trap DNAHalf life (s) K d (nM) 130 (2 min) (<1 min, FAST/ 53 permissive) 6900 (115 min, SLOW/ 0.4 nonpermissive) terB C6 Mulcair et al. (2006) Cell 125,

Unwinding ter from the “nonpermissive” direction springs a “molecular mousetrap” Releasing C6 springs the trap DNAHalf life (s) K d (nM) 130 (2 min) (<1 min, FAST/ 53 permissive) 6900 (115 min, SLOW/ 0.4 nonpermissive) terB C6 5’ 3’ Mulcair et al. (2006) Cell 125,

Unwinding ter from the “nonpermissive” direction springs a “molecular mousetrap” Releasing C6 springs the trap Mulcair et al. (2006) Cell 125,

Unwinding ter from the nonpermissive direction springs a “molecular mousetrap” Releasing C6 springs the trap Mulcair et al. (2006) Cell 125,

Topoisomerase II unlinks the replicated chromosomes Topoisomerase II - Cuts DNA and passes one duplex through the other. Class II topoisomerases include: Topo IV and DNA gyrase

Summary: What problems do these proteins solve? Tyr OH attacks PO4 and forms a covalent intermediate Structural changes in the protein open the gap by 20 Å!

FunctionE. coliSV40 (simian virus 40) HelicaseDnaBT antigen Primase Primer removal Primase (DnaG) pol I’s 5’-3’exo pol  primase FEN 1 (also RNaseH) Polymerase Corepol III ( , ,  subunits ) pol ,  Clamp loader  complex RF-C Sliding clamp  PCNA ssDNA bindingSSBRF-A Remove +sc at fork (swivel) gyrasetopo I or topo II Decatenationtopo IVtopo II LigaseDNA ligaseDNA ligase I … other model systems include bacteriophage T4 and yeast Summary: What problems do these proteins solve?

The ends of (linear) eukaryotic chromosomes cannot be replicated by the replisome. Not enough nucleotides for primase to start last lagging strand fragment Chromosome ends shorten every generation!

Telomere shortening signals trouble! 1. Telomere shortening releases telomere binding proteins (TBPs) 2. Further shortening affects expression of telomere- shortening sensitive genes 3. Further shortening leads to DNA damage and mutations. Telomere binding proteins (TBPs)

Telomerase replicates the ends (telomeres) Telomere ssDNA Telomerase extends the leading strand! Synthesis is in the 5’-->3’ direction. Telomerase is a ribonucleoprotein (RNP). The enzyme contains RNA and proteins. The RNA templates DNA synthesis. The proteins include the telomerase reverse transcriptase TERT.

Telomerase cycles at the telomeres Telomere ssDNA TERT protein TER RNA template

Telomerase extends a chromosome 3’ overhang

Conserved structures in TER and TERT Core secondary structures shared in ciliate and vertebrate telomerase RNAs (TERs). (Sequences highly variable.) nucleotides 1000s of nucleotides TERT protein sequences conserved 1300 nucleotides

Starting and stopping summary 1.DNA replication is controlled at the initiation step. 2.DNA replication starts at specific sites in E. coli and yeast. 3.In E. coli, DnaA recognizes OriC and promotes loading of the DnaB helicase by DnaC (helicase loader) 4.DnaA and DnaC reactions are coupled to ATP hydrolysis. 5.Bacterial chromosomes are circular, and termination occurs opposite OriC. 6.In E. coli, the helicase inhibitor protein, tus, binds 7 ter DNA sites to trap the replisome at the end. 7.Eukaryotic chromosomes are linear, and the chromosome ends cannot be replicated by the replisome. 8.Telomerase extends the leading strand at the end. 9.Telomerase is a ribonucleoprotein (RNP) with RNA (template) and reverse-transcriptase subunits.